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Beama Conference March 2011. George Paterson, Director of Sales. Scope of today. Alternative Lithium chemistries of the future Potential advantages Issues to overcome Impact on the design of batteries Other influencing factors What that means to the specification of future vehicles.
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Beama ConferenceMarch 2011 George Paterson, Director of Sales
Scope of today • Alternative Lithium chemistries of the future • Potential advantages • Issues to overcome • Impact on the design of batteries • Other influencing factors • What that means to the specification of future vehicles
Short Biography • George Paterson, Director of Sales with Axeon • 28 years in industry of which 7 years as Engineering Manager with Axeon • Last 4 years in sales roles • 11 years experience with batteries • gpaterson@axeon.com • +44 7788417873
About Axeon’s Volume production; conversion of Peugeot vehicles for the leading British vehicle converter. Range includes cars, people carriers and vans Designing and developing PHEV packs for JLR The world’s most powerful passenger car battery for the 102EX Rolls-Royce Phantom Experimental Electric • HEV sports car: developing leading-edge technology for premium European manufacturer Over a million vehicle miles driven since 2007 = 20MW of batteries shipped • Company overview • Dundee HQ • £64m revenue (2008) • 450 employees • 5 locations in Europe
Why Lithium ion? Cell Chemistries (Relative Energy Density) Lighter Smaller High coulombic efficiency 100% Green Low self-discharge
Cell Chemistry - The Challenges • Reduce cost – materials (raw and synthesis) reduce by 50% per kWh? • Improve safety – short circuits thermal run away, over-charge, over-discharge • Cycle life – cycle life 10,000s for HEVs • Calendar life - 10 years (transport) • Power Density – HEV, PHEV • Energy Density – PHEV, EV, load leveling
Main contender cell chemistries To Be Confirmed
Relative theoretical energy densities Dynamite = 1375 Wh/kg Wood = 4000 Wh/kg Petrol = 12000 Wh/kg – highly energy inefficient
EVs, HEVs, & PHEVs Electric Vehicles: All electric, battery power/electric motor, 70 – 130 mile range Energy density important, 15-50kWh typical Hybrid Electric Vehicles: Internal combustion engine is main drive, 400 mile range Battery recovers some of the braking energy Electric motor and battery provide power boost Power density important , 0.5-5kWh typical Plug-in Hybrid Electric Vehicles: Battery/electric motor drive, with internal combustion engine electricity generator 30 mile range on battery, then internal combustion engine used to provide extended range. Both energy and power density important, 10-25kWh typical
Potential for Cost Reduction • For a 25kWh, ~300V EV Battery Pack Axeon Technologies Yano Research Ltd MenahemAnderman, AABC 2010
Plastic case. Robust. Easy packaging, Inexpensive. Stacked or jelly roll electrodes. Cylindrical/Prismatic metal case (steel / aluminium). Robust, Easy packaging, Expensive, Jelly roll or stacked electrodes. High energy density, Good heat dissipation, Lithium Rechargeable Cell Constructions • Pouch cell. Vulnerable, Inexpensive, Design freedom on dimensions, Difficult packaging, High energy density but reduced by packaging, Can be prone to swell and leak, Less danger of explosion (cell bursts), Good heat dissipation
Main Parts of a Battery Battery Management System Contactors for switching Current shunt to measure amps in and out of the battery Busbars and traction cables Connectors Fuses Complete HVFE
Battery Housing • Currently steel used in many designs. • New high strength, lightweight steels and processes being developed for batteries. • Aluminium fabrications and sections being developed for batteries with integrated thermal management. • Increasing use of composites and carbon fibre used for high specification batteries, especially in performance cars.
Summary of components for a LiFePO4 27kWh battery • Current mass 380Kg • 10% of a battery volume and weight is BMS and HV components • Another 5-10% is taken up with wiring and bus-bars • 15-20% is in the housing and support structure • 25-35% of battery weight is non cell content
Battery Charging In theory you can charge a battery in 10 minutes, BUT: Fast charging not always practical. Charging a 50kWh battery in 10 minutes would require a 300 kW power supply. However 50kW DC chargers are beginning to roll out Most EVs are used in city areas so 160 km range is more than adequate Lithium batteries can be charged at anytime, they do not suffer memory effect So, If opportunist charging is available then perhaps smaller capacity, lighter and less expensive batteries are the answer for urban environments
Fast Charging • 50kW DC fast charger • Could fully recharge small City EV in 30 minutes • Or provide short boosts • Located at service stations and supermarkets • Battery capacity could be reduced, less cost, weight and size • HV components and bus-bars have to be rated accordingly • Cells may have to be actively cooled during charge
Inductive Charging • System could be buried in the road surface • Located at major junctions where traffic stops • Can be used for taxis and buses as well as private EV’s • Location at supermarkets and car parks • Battery capacity could be reduced so less cost, weight and size
Future pack concepts 2010 35kWh 250km 2015 35kWh 250km 2025 66kWh 500km Credit EDAG
Summary • Improvements in cell chemistry will make batteries, smaller, light and cheaper giving improved range and performance • Electronic components within a battery also have to advance to save space and weight • Charging methods can have a big impact on the size of batteries • New materials and processes for the construction of battery housings will be required to fully benefit from advancements in cells • Combining all the above will revolutionise EV’s, HEV’s and PHEV’s of the future • Target of 0.5kWh/Kg by 2030 would give a 27kWh battery a weight of 54Kg and 42l expected range 200km
